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UNITED STATES MARINE CORPS ENGINEER EQUIPMENT INSTRUCTION COMPANY
MARINE CORPS DETACHMENT
14813 EAST 8TH ST
FORT LEONARD WOOD, MISSOURI 65473
LESSON PLAN
SOILS
LESSON ID EAC-A02
ENGINEER ASSISTANT CHIEFS COURSE
CID- A16EAV1
REVISED 08/01/14
APPROVED BY ________________________________ DATE AUG 2014
LP-2
INTRODUCTION (5 Min)
(ON CAG #1)
1. GAIN ATTENTION. All construction projects, whether they are horizontal,
or vertical in design require a solid foundation. As engineers, you must be
able to determine the capabilities of the soil on which the structure is to
be built. As engineer assistant chiefs, you must also know how to improve
the soil’s capabilities to accomplish your mission. Installing a structure
on soil that is incapable of carrying the loads that will be applied will
lead to failure.
_____________________________________________________________________________
_____________________________________________________________________________
_____________________________________________________________________________
2. OVERVIEW. The purpose of this period of instruction is to provide you
with the knowledge on how to perform a field identification test, classify
the soil, determine the California Bearing Ratio, determine the suitability
of the soil, selecting a soil stabilization technique, determining the amount
of admixture and applying proper mechanical stabilization to the soil as
required to meet construction design requirements.
3. LEARNING OBJECTIVES.
a. TERMINAL LEARNING OBJECTIVES.
(1) Given an unidentified soil sample, and SL-3 complete soil test
kit and references, perform hasty soil analysis to determine a two letter
Unified Soil Classification System (USCS) classification, California Bearing ratio (CBR), and moisture content. (1361-XENG-2001)
b. ENABLING LEARNING OBJECTIVES.
(1) With the aid of references, state the procedures used to classify
soil per the MCRP 3-17.7G.(1361-XENG-2001a)
(2) Given a soil test kit, a training area, an unidentified soil
sample, soils laboratory, and references, perform soil analysis using the
(USCS) per the MCRP 3-17.7G. (1361-XENG-2001b)
(3) Given a soil test kit, a training area, an unidentified soil
sample, and references, operate the Dual-Mass Dynamic Cone Penetrometer (DCP)
to determine the (CBR) of soil per the MCRP 3-17G. (1361-XENG-2001c)
(4) Given a soil test kit, a training area, an unidentified soil
sample, and references, determine the moisture content of soil using the
speedy moisture tester and the (DCP) with the Soil Moisture Probe (SMP) per
the MCRP 3-17.7G. (1361-XENG-2001d)
INSTRUCTOR NOTE
Have students read learning objectives to themselves.
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(5) Given a USCS classification and references, determine the
suitability of the soil for the intended mission per the MCRP 3-17.7G.
(1361-XENG-2001e)
(6) Given a completed field identification analysis, soil
suitability, and references, apply proper soil stabilization techniques per
the MCRP 3-17.7G. (1361-XENG-2001f)
(7) Given a mission to construct a horizontal or vertical facility
requiring soil stabilization and references, determine compaction
requirements per the MCRP 3-17.7I. (1361-XENG-2001g)
4. METHOD/MEDIA. This lesson will be taught by the lecture, demonstration
and practical application method. I will be aided by the use of computer
generated graphics.
5. EVALUATION. You will be evaluated by a performance and written
examinations immediately following this period of instruction in accordance
with the training schedule.
6. SAFETY/CEASE TRAINING (CT) BRIEF. There are no safety or cease training
requirements for this class.
TRANSITION: Are there any questions about what we will be covering, or how
and when you will be evaluated? If there are no questions, let’s begin by
discussing how soil is formed.
_____________________________________________________________________________
_____________________________________________________________________________
_____________________________________________________________________________
(ON CAG #2)
BODY (7HR 40MIN)
1. SOIL FORMATION. (20 Min)
The term “soil” refers to the entire unconsolidated material that overlies
and is distinguishable from bedrock. Soil is composed principally of the
disintegrated and decomposed particles of rock. It also contains air and
water as well as organic matter derived from the decomposition of plants and
animals. Soil is a heterogeneous accumulation of cemented or weakly cemented
mineral grains enclosing voids of varying sizes. These mineral grains range
in size from large boulders to single mineral crystals of microscopic size.
Soil is created by the process of rock weathering and often the additional
process of transportation.
INSTRUCTOR NOTE
Explain Instructional Rating Forms to the students.
INSTRUCTOR NOTE
Refer to the training schedule to give the exact date of the exam.
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(ON CAG #3)
a. Weathering. Weathering is the physical or chemical breakdown of
rock. These physical and chemical processes will vary with the environmental
conditions present.
(ON CAG #4)
(1) Physical Weathering. The disintegration of rock. It breaks rock
masses into smaller pieces without altering the chemical composition of the
pieces. Processes that produce physical weathering include:
(ON CAG #5)
(a) Unloading. Extensive fracturing that results from the relief
of pressure on a rock unit due to the removal of overlying material.
(ON CAG #6)
(b) Frost Action. Is the fracturing that occurs when trapped
moisture in rocks freeze. This moisture can expand up to one tenth of its
original volume, creating pressure of up to 4000 pound per square inch (psi).
(ON CAG #7)
(c) Organism Growth. Trees and plants readily grow in the joints
of rock masses near the surface. The wedging action caused by root growth
hastens the disintegration process.
(ON CAG #8)
(d) Abrasion. Sediments suspended in wind or fast-moving water
can act as abrasives to physically weather rock masses. Rock particles
carried by glacial ice can also be very abrasive.
(ON CAG #9)
(2) Chemical Weathering. The decomposition of rock through the
chemical reactions that take place between minerals of the rock and the air,
water or dissolved chemicals in the atmosphere. Chemical weathering
processes include:
(ON CAG #10)
(a) Oxidation. The chemical union of a compound with oxygen. An
example is rusting, which is the chemical reaction of oxygen, water and the
iron mineral pyrite which forms ferrous sulfate.
(ON CAG #11)
(b) Hydration. The chemical union of a compound with water.
(ON CAG #12)
(c) Carbonation. The chemical process in which carbon dioxide
from the air unites with various minerals to form carbonates.
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(ON CAG #13)
b. Formation Methods.
(1) Residual Soils. Residual soils are formed where the rock
material has been weathered in place. While mechanical (physical) weathering
may occur, chemical weathering is the dominant factor.
(2) Transported Soils. By far, most soils that we encounter are
materials that have been transported and deposited at a new location. Three
major forces - glacial ice, water and wind - are the transporting agents;
hence, these soils can be divided into glacial deposits, sedimentary (water-
laid) deposits and eolian (wind-laid) deposits.
(ON CAG #14)
TRANSITION: Now that we have discussed weathering, the different types of
weathering and how soil is formed, are they any questions? If there are no
questions I have some questions for you. (a) What are the two types of
weathering called? Physical and Chemical (b) What are the two types of soil
formation methods? Residual and Transported Now that we have covered
weathering, the different types of weathering and how soil is formed let’s
take a look at soil characteristics.
_____________________________________________________________________________
_____________________________________________________________________________
_____________________________________________________________________________
___
(ON CAG #15)
2. SOIL CHARACTERISTICS. (25 Min)
The physical characteristics of a soil aid in determining the engineering
characteristics. These properties form the basis for the system of soil
classification used to identify soil types. The physical characteristics of
soil particles are size and shape.
(ON CAG #16)
a. Grain (Particle) Size. Soils are divided into groups based on the
size of the particle grains in the soil mass. Particle size is determined
through the use of sieves. A sieve is a screen attached to a metal frame.
There are two types of sieves, inch and numbered.
(1) Inch Sieves. These sieves range in size from 3” to 1/4” and are
measured by the clear distance between the wires.
(2) Numbered Sieves. These sieves are numbered from #4 to #200 and
are measured by the number of openings per linear inch.
(3) Passing or Retained. If a particle will not pass through a
screen of a certain size opening, it is said to be “retained on” that sieve.
The following table lists size groups within the Unified Soils Classification
System:
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(ON CAG #17)
(ON CAG #18)
b. Particle Shape. Two general shapes are normally recognized: bulky
and platy. The bulky shapes include particles which are relatively equal in
all three dimensions. In platy shapes, one dimension is very small compared
to the other two; for example, a thick book would be considered bulky, but a
page of a book would be platy.
(1) Bulky Shapes. Bulky shapes are subdivided depending on the
amount of weathering that has acted on them.
(a) Angular. Particles that have recently been broken up are
angular. They are characterized by jagged projections, sharp ridges and flat
surfaces. The interlocking characteristics of angular gravels and sands
generally make them the best materials for construction. These particles are
seldom found in nature because the weathering processes normally wear them
down in a relatively short time.
(b) Sub-angular. Particles that have been weathered until the
sharper points and ridges of their original angular shape have been worn off.
The particles are still very irregular in shape and are excellent for
construction.
(c) Sub-rounded. Is the Particles on which weathering has
progressed even further. Still somewhat irregular in shape, they have no
sharp corners and few flat areas. They are still adequate for construction.
(d) Rounded. Particles in which all projections have been
removed and few irregularities remain. The particles approach spheres of
varying sizes. They are not desirable in construction unless the rounded
shape can be altered by crushing.
(ON CAG #19)
(2) Platy Shapes. As previously stated, platy particles are
extremely thin compared to their length and width. Only fine grained
material of the clay variety has this characteristic shape. It is generally
Sieve size
Passing Retained on
Size
Groups
Cobbles No Maximum Size 3 inch
Gravels 3 inch Number 4
Sands Number 4 Number 200
Fines Number 200 No Minimum Size
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accepted that platy grains are responsible for the plasticity of clay. Platy
particles are highly compressible under static load. Several phenomena are
associated with platy shapes.
(a) Clays frequently undergo very large volume changes with
variations in moisture content. Evidence of this can be seen in the
shrinkage cracks that develop in a lake bed as it dries.
(b) Unpaved clay roads, although often hard when sun baked, lose
stability and turn to mud during rainstorms.
(c) In general, the higher the moisture content of a clay or
silt, the less its strength and hence it’s bearing capacity.
(ON CAG #20)
c. Gradation. The distribution of particle sizes within a soil mass is
known as its gradation. Gradation is described by two main headings.
(1) Well-Graded Soil. A well-graded soil is defined as having a good
representation of all particle sizes from the largest to the smallest.
Additionally, the shape of the grain size distribution curve is smooth, the
coefficient of curvature is between 1-3, and the coefficient of uniformity
must be >4 for gravel and >6 for sand.
(2) Poorly-Graded Soil. There are two types of poorly-graded soil.
(a) Uniformly graded soil consists primarily of particles of
nearly the same size.
(b) Gap Graded soil contains both large and small particles, but
the gradation continuity is broken by the absence of some particle sizes.
(ON CAG #21)
TRANSITION: Now that we have discussed soil characteristics, the different
types of particle sizes and shapes, and gradation, are they any questions?
If they are no questions I have some questions for you. (a) How is particle
size determined? Using a sieve (b) What are the two types of poorly graded
soil? Uniformly and Gap Graded
Now that we have covered soil characteristics, the different types of
particle sizes, shapes and gradation, let’s take a ten minute break and then
we will take a look at the Unified Soil Classification System (USCS).
_____________________________________________________________________________
_____________________________________________________________________________
_____________________________________________________________________________
(BREAK 10 Min)
TRANSITION: Before the break we covered SOIL CHARACTERISTICS. Do you have any
questions? If not, let’s talk about UNIFIED SOIL CLASSIFICATION SYSTEM
(USCS).
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(ON CAG #22)
3. UNIFIED SOIL CLASSIFICATION SYSTEM (USCS). (15 Min)
Soils seldom exist separately as sand, gravel, or any other single component
in nature. They are usually mixtures with varying proportions of different
sized particles. Each component contributes to the characteristics of the
mixture. The USCS is based on the characteristics which indicate how a soil
will behave as a construction material. These characteristics include the
percent of gravel, sand and fines; gradation; and plasticity. The physical
properties determined by field identification techniques are used to classify
the soil. Once an accurate classification is obtained, the potential
behavior of the soil under traffic or foundation loads can be determined.
(ON CAG #23)
a. Categories. In the USCS, all soils are divided into three major
categories: Coarse grained, fine grained, and peat. The first two are
differentiated by grain size, whereas the third is identified by the presence
of large amounts of organic material.
(1) Coarse-Grained Soils. A coarse-grained soil is classified as a
gravel if more than half the coarse fraction, by weight, is larger than a No.
4 sieve. It is a sand if more than half the coarse fraction, by weight, is
smaller than a No. 4 sieve. In general, there is no clear-cut boundary
between gravelly and sandy soils. As far as behavior is concerned, the exact
point of division is relatively unimportant. Where a mixture occurs, the
primary name is the predominant fraction, in percent by weight, and the minor
fraction is used as an adjective. For example, a sandy gravel would be a
mixture containing more gravel than sand, by weight. Coarse grained soils
have better internal drainage than fine-grained soils. Observations of the
soil should be made in both disturbed and undisturbed conditions.
NOTE: If fines interfere with free-draining properties (as may occur with
plastic fines), use the double symbol (GW-GM, GW-GC, and so on)indicating
that such soils will be classed with soils having from 5 to 12 percent fines.
(a) Subdivided into two divisions:
1 Gravels and gravelly soils (G).
2 Sands and sandy soils (S).
b. Groups. Each of the major categories is further subdivided into
groups and a letter symbol is assigned to each group. The primary letter of
a classification relates to the soil group, while the secondary letter is
descriptive of the soil’s characteristics. The following symbols are
combined to describe the soil mixture:
(ON CAG #24)
SOIL GROUPS SYMBOL
Gravel G
Sand S
Silt M
Clay C
Organic O
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(ON CAG #25)
SOIL CHARACTERISTICS SYMBOL
Well Graded W
Poorly Graded P
High Compressibility H
Low Compressibility L
*M and C are also used as secondary letters of the USCS
(ON CAG #26)
TRANSITION: Now that we have discussed the Unified Soil Classification
System (USCS), and the group characteristics, are they any questions? If
they are no questions I have some questions for you. (a) What is the USCS
based on? The characteristics which indicate how a soil will behave as a
construction material (b) What is the symbol for gravel based of the USCS? G
Now that we have covered the Unified Soil Classification System (USCS), and
the group characteristics, take a look at the Field Identification of Soil.
_____________________________________________________________________________
_____________________________________________________________________________
_____________________________________________________________________________
___
(ON CAG #27)
4. FIELD IDENTIFICATION OF SOIL. (50 Min)
The soil types of an area are an important factor in selecting the exact
location of airfields and roads. The military engineer, construction
foreman, and members of engineer reconnaissance parties must be able to
identify soils in the field so that the engineering characteristics of the
various soil types encountered can be compared. Several simple field
identification tests are described below. Each test may be performed with a
minimum of time and equipment, although seldom will all of them be required
to identify a given soil. The number of tests required depends on the type
of soil and the experience of the individual performing them. By using these
tests, soil properties can be estimated and materials can be classified.
Such classifications are approximations and should not be used for designing
permanent or semi-permanent construction.
a. Soil Surveys. The survey of soil conditions at the site of proposed
military construction provides information about the nature, extent and
condition of soil layers. It is vital to both the planning and execution of
military construction operations.
(1) Sources Useful in Planning Soil Surveys. Any of the following
sources of information can be useful to the Marine engineer:
(a) Intelligence Reports. Intelligence reports which include
maps and studies of soil conditions usually are available for areas in which
military operations have been planned. These reports are a source of
information on geology, topography, terrain conditions, climate, and weather
conditions.
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(b) Local Inhabitants. Local inhabitants may provide information
to supplement Intel reports or provide information about areas for which
Intel reports are unavailable. Data obtained from this source could include
possible locations of borrow pits, sand and gravel deposits, and peat or
highly organic soils.
(c) Maps and Aerial Photographs. Thorough inspection of maps
provide information about topography that can be useful to the trained soils
analyst such as locations of hills, mountains, ridges, levees, sand dunes and
alluvial fans. Aerial photographs allow the trained observer to identify
landforms, slopes, drainage patterns, erosion characteristics and land use.
(2) Soil Exploration. Soil exploration, or soil boring, is nothing
more than gathering soil samples for examining, testing and classifying.
Three methods of obtaining samples are available to the military engineer:
taking samples from the surface, from excavations already in existence or
digging a test hole. Regardless of the method employed, a quantity of soil
that will fit in a sandbag is required for analysis. When digging a test
hole or conducting a soil boring, the following procedures should be
followed:
(a) Locate soil borings at or adjacent to the point of interest.
(b) Ensure that the bore- hole is deep enough to penetrate the
topsoil layer.
(c) Observe the color, moisture and number of layers exposed
within the bore hole.
(d) On large scale horizontal projects (roads or airfields),
conduct multiple borings and compare data as required.
(ON CAG #28 - 29)
b. Soils Test Kit. The soils test kit is an invaluable tool for
classifying the soil types and strength of soil on or near your project site.
The kit contains three field deployable cases equipped with the essential
items to conduct a series of field identification tests to determine
important characteristics of the soil. Case one contains equipment to
complete the field identification. Case two contains the Dynamic Cone
Penetrometer (DCP) to test the California Bearing Ratio test. Case three
contains various tools from the data acquisition system to the speedy
moisture tester.
(1) Requires a small amount of soil to conduct these field tests.
(2) The field tests can be conducted in a reasonably short period of
time compared to a full laboratory analysis. Time to complete the field
identification tests should be 15-20 minutes approximately.
(3) From this series of field tests, the properties of the soil can
be estimated with reasonable accuracy.
(4) Procedures. An approximate identification of coarse grained soil
can be made by spreading a dry sample on a flat surface and examining it,
noting particularly, grain size, gradation, grain shape and particle
hardness. All lumps in the sample must be thoroughly pulverized to expose
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individual grains and to obtain a uniform mixture when water is added to the
fine grain portion. A rubber-faced or wooden pestle and a mixing bowl are
recommended for pulverizing. Lumps can also be pulverized by placing a
portion of the sample on a firm, smooth surface and using the foot to mash
it. If an iron pestle is used for pulverizing, it will break up the mineral
grains and change the character of the soil; therefore, using an iron pestle
is discouraged. Tests for identification of the fine grained portion of any
soil are performed on the portion of the material that passes a Number 40
sieve. This is the same soil fraction used in the laboratory for Atterberg
limits tests, such as plasticity. If the sieve is not available, a rough
separation may be made by spreading the material on a flat surface and
removing the gravel and larger sand particles. Fine grained soils are
examined primarily for characteristics related to plasticity.
c. Equipment. Practically all the tests to be described can be
performed with no equipment or accessories other than a small amount of
water. However, the accuracy and uniformity of results is greatly increased
by the proper use of certain equipment. The following equipment is available
in nearly all engineer units (or may be improvised) and is easily
transported:
(1) A Number 40 US standard sieve. Any screen with about 40 openings
per lineal inch could be used, or an approximate separation may be used by
sorting the materials by hand. Number 4 and Number 200 sieves are useful for
separating gravels, sands, and fines.
(2) A pick and shovel or a set of entrenching tools for obtaining
samples. A hand earth auger is useful if samples are desired a few feet
below the surface.
(3) A spoon issued as part of mess equipment for obtaining samples
and for mixing materials with water to the desired consistency.
(4) A bayonet or pocket knife for obtaining samples and trimming them
to the desired size. A small mixing bowl with a rubber faced or wooden pestle
for pulverizing the fine grained portion of the soil. Both may be improvised
by using a canteen cup and a wooden dowel.
(5) Several sheets of nonabsorbent paper for rolling samples.
(6) A pan and a heating element for drying samples.
d. Testing. The procedures outlined below will result in a USCS
classification. Many of the tests listed are not in sequential order.
Utilize the wire diagram on page 12 to determine required tests and the order
in which they should be performed. This wire diagram is an extract from FM
5-472, “Materials Testing”.
(ON CAG #30)
INTERIM TRANSITION: Now that we have discussed conducting a field
identification of soils and all the necessary equipment needed to do so,
let’s take a break then we will move outside for a demonstration of the field
identification of soils.
_____________________________________________________________________________
_____________________________________________________________________________
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_____________________________________________________________________________
___
(BREAK 10 Min)
TRANSITION: Before the break we covered FIELD IDENTIFICATION OF SOIL. Do you
have any questions? If not, let’s start the demonstration.
INSTRUCTOR NOTE:
Move students to the outside Southwest corner of Brown Hall and assign them
into 2-4 man teams
( CAG # 31)
INSTRUCTOR DEMONSTRATION:
(1) Select a random but typical sample of soil.
(2) Perform visual examination, noting color, particle shape, and
maximum size aggregate.
(3) Separate the gravel.
(a) Remove from the sample all particles retained on the #4 sieve.
(b) Estimate the percent of gravel.
(4) Odor test
(a) Heat the sample with a match or open flame.
(b) If the odor is musty or foul smelling, there is a strong
indication that organic material is present.
(5) Sedimentation test
DEMONSTRATION. (1 Hr) Have the students gather around the test table for
a demonstration of a field identification of a soil samples.
STUDENT ROLE: Observe field identification of soil demonstration
utilizing the proper steps taught.
INSTRUCTOR(s) ROLE: Demonstrate a field identification of soil making
sure to assign the correct two letter identification symbol according to
the Unified Soils Classification System (USCS).
1. SAFETY BRIEF: No safety concerns with this class.
2. SUPERVISION & GUIDANCE: Be sure to have students follow along in
their student outline along with the instructor’s supervision.
DEBRIEF: Now that I have demonstrated a field identification of soil,
assigned a two letter symbol designator according to the USCS, you will
now be able to properly conduct your own field identification test.
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(Both methods use -4 materials only)
CANTEEN CUP METHOD
(a) Place the sample in a canteen cup, mark the soil depth, and
fill it with water.
(b) Shake the mixture vigorously.
(c) Allow the mixture to stand for 30 seconds to settle out.
(d) Pour the water containing the suspended fines into another
container.
(e) Repeat steps (b) through (d) until the water poured off is
clear.
(f) Dry the soil left in the cup (sand).
(g) Estimate the percent of sand.
MASON JAR METHOD
(a) Place approximately 1” of soil into a mason jar. Draw a line
on the Mason jar to represent 100% of material to be tested.
(b) Add water to within 1” from top of jar (about 5” of water).
(c) Shake mixture vigorously for 4 minutes.
(d) Place jar on flat, undisturbed surface and allow settling for
30 seconds.
(e) Mark settlement line on Mason jar. This represents % settled.
(f) Estimate % settled in relation to the original 100% line.
(g) Determine % sand using the following equation:
% settled X % sand & fines = %S
100
(6) Compare the gravels, sands, and fines.
(a) The gravels have been estimated in test (3) step (b).
(b) The sands have been estimated in test (5) step (g).
(c) Estimate the percent of fines. 100 - (%G + %S) = %F
(7) Grit or Bite test
(a) Place a pinch of the sample between teeth and bite.
(b) If the sample feels gritty, the sample is silt (ML) or sand
(S).
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(c) If the sample feels floury, the sample is clay (C).
(8) Feel test
(a) Rub a portion of dry soil over a sensitive portion of the skin,
such as the inside of the wrist.
(b) If the feel is harsh and irritating, the sample is silt (ML) or
sand (S).
(c) If the feel is smooth and floury, the sample is clay (C).
(9) Wet Shaking test
(a) Place the pat of moist (not sticky) soil in the palm of the
hand (the volume is about ½ inch)
(b) Shake the hand vigorously and strike it against the other hand.
(c) Observe how rapidly water rises to the surface.
(d) If it is fast, the sample is silty (M). If there is no
reaction, the sample is clayey (C).
(10) Thread test
(a) Form a ball of moist soil (marble size).
(b) Attempt to roll the ball into a thread 1/8 inch in diameter.
(c) If thread is easily obtained, it is clay (C).
(d) If thread cannot be obtained, it is silt (M).
(11) Ribbon test
(a) Form a cylinder of soil that is approximately the size and
shape of a cigar.
(b) Flatten the cylinder over the index finger with the thumb,
attempting to form a ribbon 8 to 9 inches long, 1/8 to ¼ inch thick, and 1
inch wide.
(c) If 8 to 9 inches is obtained, it is (CH); if less than 8 inches
is obtained, it is (CL); if there is no ribbon (less than 3”), it is silt
(M).
(12) Shine test
(a) Draw a smooth surface, such as a knife blade or thumbnail, over
a pat of slightly moist soil.
(b) If the surface becomes shiny and lighter in texture, the sample
is highly plastic compressible clay (CH).
(c) If the surface remains dull, the sample is low plasticity
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compressible clay (CL).
(d) If the surface remains very dull or granular, the sample is
silt (M).
(13) Dry Strength test
(a) Form a moist pat 2 inches in diameter by ½ inch thick.
(b) Allow it to dry with low heat.
(c) Place the dry pat between the thumbs and index fingers only and
attempt to break it.
(d) If breakage is easy, it is slightly plastic silt (ML).
(e) If breakage is difficult, it is medium plastic and medium
compressible clay (CL) or highly compressible silt (MH).
(f) If breakage is impossible, it is highly plastic and highly
compressible clay (CH).
(1) Select a random but typical sample of soil.
(2) Perform visual examination, noting color, particle shape, and
maximum size aggregate.
(3) Separate the gravel.
(a) Remove from the sample all particles retained on the #4
sieve.
(b) Estimate the percent of gravel.
(4) Odor test.
(a) Heat the sample with a match or open flame.
(b) If the odor is musty or foul smelling, there is a strong
indication that organic material is present.
(5) Sedimentation test.
(Both methods use -4 materials only)
CANTEEN CUP METHOD
(a) Place the sample in a canteen cup, mark the soil depth, and
fill it with water.
(b) Shake the mixture vigorously.
(c) Allow the mixture to stand for 30 seconds to settle out.
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(d) Pour the water containing the suspended fines into another
container.
(e) Repeat steps (b) through (d) until the water poured off is
clear.
(f) Dry the soil left in the cup (sand).
(g) Estimate the percent of sand.
MASON JAR METHOD
(a) Place approximately 1” of soil into a mason jar. Draw a line
on the Mason jar to represent 100% of material to be tested.
(b) Add water to within 1” from top of jar (about 5” of water).
(c) Shake mixture vigorously for 4 minutes.
(d) Place jar on flat, undisturbed surface and allow settling for
30 seconds.
(e) Mark settlement line on Mason jar. This represents %
settled.
(f) Estimate % settled in relation to the original 100% line.
(g) Determine % sand using the following equation:
% settled X % sand & fines = %S
100
(6) Compare the gravels, sands, and fines.
(a) The gravels have been estimated in test (3) step (b).
(b) The sands have been estimated in test (5) step (g).
(c) Estimate the percent of fines. 100 - (%G + %S) = %F
(7) Grit or Bite test
(a) Place a pinch of the sample between teeth and bite.
(b) If the sample feels gritty, the sample is silt (ML) or sand
(S).
(c) If the sample feels floury, the sample is clay (C).
(8) Feel test
(a) Rub a portion of dry soil over a sensitive portion of the
skin, such as the inside of the wrist.
(b) If the feel is harsh and irritating, the sample is silt (ML)
or sand (S).
LP-17
(c) If the feel is smooth and floury, the sample is clay (C).
(9) Wet Shaking test
(a) Place the pat of moist (not sticky) soil in the palm of the
hand (the volume is about ½ inch)
(b) Shake the hand vigorously and strike it against the other
hand.
(c) Observe how rapidly water rises to the surface.
(d) If it is fast, the sample is silty (M). If there is no
reaction, the sample is clayey (C).
(10) Thread test
(a) Form a ball of moist soil (marble size).
(b) Attempt to roll the ball into a thread 1/8 inch in diameter.
(c) If thread is easily obtained, it is clay (C).
(d) If thread cannot be obtained, it is silt (M).
(11) Ribbon test
(a) Form a cylinder of soil that is approximately the size and
shape of a cigar.
(b) Flatten the cylinder over the index finger with the thumb,
attempting to form a ribbon 8 to 9 inches long, 1/8 to ¼ inch thick, and 1
inch wide.
(c) If 8 to 9 inches is obtained, it is (CH); if less than 8
inches is obtained, it is (CL); if there is no ribbon (less than 3”), it is
silt (M).
(12) Shine test
(a) Draw a smooth surface, such as a knife blade or thumbnail,
over a pat of slightly moist soil.
(b) If the surface becomes shiny and lighter in texture, the
sample is highly plastic compressible clay (CH).
(c) If the surface remains dull, the sample is low plasticity
compressible clay (CL).
(d) If the surface remains very dull or granular, the sample is
silt (M).
(13) Dry Strength test
(a) Form a moist pat 2 inches in diameter by ½ inch thick.
(b) Allow it to dry with low heat.
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(c) Place the dry pat between the thumbs and index fingers only
and attempt to break it.
(d) If breakage is easy, it is slightly plastic silt (ML).
(e) If breakage is difficult, it is medium plastic and medium
compressible clay (CL) or highly compressible silt (MH).
(f) If breakage is impossible, it is highly plastic and highly
compressible clay (CH).
LP-19
SE
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LP-20
( CAG # 32)
INTERIM TRANSITION: Now that we have seen a demonstration of the field
identification of soil, how to classify it according to the Unified Soil
Classification System (USCS), let’s move into the practical application
portion in which we will conduct a field identification of soil to include
assigning a two letter designator according to the USCS. Please proceed to
your assigned sites outside.
_____________________________________________________________________________
_____________________________________________________________________________
_____________________________________________________________________________
INSTRUCTOR NOTE:
Perform the following practical application
PRACTICAL APPLICATION: (1.5 Hrs) Have the students conduct multiple field
identification of various soil samples.
PRACTICE: Conduct field identification of soil utilizing the proper steps
taught
PROVIDE-HELP: Walk around the classroom and aid the students in their
interpretation of the field tests along with making sure they assign the
correct two letter identification symbol according to the Unified Soils
Classification System (USCS).
SAFETY BRIEF: No safety concerns with this class.
SUPERVISION & GUIDANCE: Be sure to follow the step by step directions
covered in your student outline along with the instructor’s supervision.
DEBRIEF: Now that we have conducted a field identification of soil, assigned
a two letter symbol designator according to the USCS, you will now be able to
properly test and identify any area in order to keep within proper
construction design requirements.
INSTRUCTOR NOTE:
Upon completion of the Soil Field Identification practical application, move
students back to the classroom.
LP-21
(ON CAG #33-36)
e. Bearing Capacity. The above soil characteristics are a measure of
the soil’s suitability to serve some intended purpose. Generally, a dense
soil will withstand greater applied loads (have greater bearing capacity)
than a loose soil. Particle size has a definite relation to this capacity.
Empirical tests show that well-graded, coarse grained soils generally can be
compacted to a greater density than fine grained soils because the smaller
particles tend to fill the spaces between the larger ones. The shape of the
grains also affects the bearing capacity. Angular particles tend to
interlock and form a denser mass, and are more stable than rounded particles,
which can roll or slide past one another. Poorly-graded soils, with their
lack of one or more sizes, leave more or greater voids and therefore a less
dense mass.
(ON CAG #37, 38)
(1) California Bearing Ratio (CBR). This system of determining soil
density was developed by the California Department of Transportation in 1929.
This system compares the density of the soil being tested to the density and
strength of crushed limestone. CBR is expressed as a percentage. i.e. a
soil which has a CBR value of 50 means it is 50% the strength of crushed
limestone.
(CAG #39-54)
(2) Dynamic Cone Penetrometer (DCP). This instrument is used to
assess the in situ strength of undisturbed soil and/or compacted materials.
The penetration rate of the DCP can be used to estimate in situ CBR, shear
strength of strata, and identify strata thickness. This instrument is
typically used to assess material properties down to a depth of 1 meter (39.4
inches) below the surface. The DCP can be used to estimate the strength of
fines and coarse grained soils, granular construction materials and weak
stabilized or modified materials however should never be used in highly
stabilized soil or materials containing a large percentage of aggregates
greater than 2 inches.
(a) Basic Operation. The operator holds the device by the handle
in a vertical or plumb position and lifts and releases the hammer from the
standard drop height. The recorder measures and records the total
penetration for a given number of blows or the penetration per blow.
(b) Initial Reading. The DCP is held vertically and the tip is
so seated such that the top of the widest part of the tip is flush with the
material to be tested. An initial reading is obtained from the vertical
scale. The distance is measured to the nearest 1 mm.
(c) Termination of Test. The test should be terminated if the
handle deviates 3” or more from the vertical or after 5 blows; the device has
not advanced more than 2 mm. A new test location should be a minimum of 12”
from the prior location.
(d) Extraction. Following completion of the test, the device
should be removed by driving the hammer upwards against the handle.
LP-22
(ON CAG #55)
f. Quality Control. Can be accomplished by several different means and
is the project manager’s single best way to ensure standards throughout the
project.
(1) Test Strip. Is the “full dress rehearsal” of a construction
project. It allows the project manager to test his plans against the actual
conditions as they exist on the project site.
(2) Speedy Moisture Tester. Allows accurate gauge of the soils
moisture content on site. A portable system used for measuring the moisture
content of a wide range of materials including soils, aggregates, dust and
powders, and liquids. The procedures are as follows:
(a) Ensure the vessel is clean prior to using.
(b) Select and prepare the sample. Some material may need to be
ground prior to testing or pulverized during the test.
(c) Weigh the sample by placing the empty measuring beaker on the
scale and zero the scale. Add small amounts of sample until the correct
sample weight of 20 grams has been reached.
(d) Add sample to the speedy vessel along with pulverizing balls
if needed.
(e) Add a minimum of two scoops of calcium carbide to the cap
cavity.
(f) While holding the speedy vessel horizontally, replace the cap
and secure the top screw to seal the vessel.
(g) Mix the sample and calcium carbide together by holding the
speedy vertically with the pressure gauge facing the ground and shake
vigorously for 5 seconds. Rotate the speedy so the pressure gauge is facing
the sky. Tap the sides to ensure the sample falls into the cap cavity and
hold this position for 1 – 2 minutes.
(h) Alternatively, if the pulverizing balls are being used, hold
the speedy horizontally and shake it in an orbital motion to make the balls
spin around the inside of the vessel. Do this for 20 seconds and then rest
for 20 seconds. Repeat this process two or three times.
(i) Take the reading by holding the speedy horizontally and at
eye level and determine the moisture content reading directly from the
pressure gauge. If it is believed that the sample contains greater than 20%
moisture, repeat the entire process, only this time reduce the sample size to
10 grams and double the reading taken from the dial.
(j) Release the pressure in the vessel by slowly unscrewing the
cap.
(k) Remove the sample from the vessel by pouring the contents
into a clean dry open container and dispose of in accordance with the MSDS.
(l) Clean the vessel and all tools and components used.
LP-23
(3) DCP with Attachments. Allows proper testing of the entire in
place characteristics of soils CBR and moisture and allows it to be graphed.
(CAG # 56)
TRANSITION: We have just discussed the California Bearing Ratio (CBR) in
conjunction with Dynamic Cone Penetrometer. Do you have any questions? If
not, let’s start the demonstration in which we will use the DCP outside on
typical Fort Leonard Wood clayey soil.
_____________________________________________________________________________
_____________________________________________________________________________
_____________________________________________________________________________
INSTRUCTOR NOTE:
Perform the following demonstration
INTERIM TRANSITION: You have just seen a demonstration of the Dynamic Cone
Penetrometer (DCP) and the Speedy Moisture Tests, let’s move into the
practical application portion.
INSTRUCTOR NOTE:
Perform the following practical application
DEMONSTRATION: (1 Hr) Have the students gather around the DCP for a
demonstration on how to use it to get a CBR rating.
STUDENT ROLE: Observe DCP demonstration utilizing the proper steps
taught.
INSTRUCTOR ROLE: Demonstrate the DCP to also include the how to utilize
the Soil Moisture Probe.
-Setup of DCP
-Manual CBR test(s)
-Automated CBR tests
-SMP tests
-Speedy Moisture test
1. SAFETY BRIEF: Give Safety brief concerning DCP handling/set-up and
SMP testing safety procedures.
2. SUPERVISION & GUIDANCE: Be sure to have students follow along in
their student outline along with the instructor’s supervision.
DEBRIEF: N/A
LP-24
INSTRUCTOR NOTE:
Upon completion of the DCP practical application, move students back to the
classroom.
(ON CAG #57)
TRANSITION: Today we have conducted a field identification of soil,
classified it according to the Unified Soil Classification System (USCS), and
discussed California Bearing Ratio (CBR) in conjunction with Dynamic Cone
Penetrometer, are they any questions? If they are no questions I have some
questions for you. (a) What two methods are used for the sedimentation test?
Canteen Cup and Mason jar method. (b) What is California Bearing Ratio use
to determine? Soil density. Lets take a ten min break and then we will talk
about soil stabilization.
(BREAK - 10 min)
TRANSITION: are there any more questions before we talk about soil
stabilization.
(ON CAG #58)
5. SOIL STABILIZATION. (30 min) Stabilized soils can often be adequate for
airfields, traffic pavements, and parking and storage areas where an all-
weather surface is required, yet traffic does not justify a higher-strength
pavement. Surface treatments are also used to provide dust control. The most
widely recognized form of stabilization is compaction, which improves the
mechanical stability of virtually any soil. Compaction also preserves the
construction strength of the soil by preventing the entry of surface water
(waterproofing). However, compaction alone is often not enough.
Stabilization is the process of blending and mixing materials with a soil to improve the soil’s strength and durability. The process may include blending
PRACTICAL APPLICATION: (1.5 Hrs) Give students a training/project
scenario (HLZ, airfield, etc.) where a training lane or distance intervals
are given enabling the use of the DCP and the SMP.
INSTRUCTOR ROLE: Ensure students set up the DCP properly to receive
readings.
STUDENT ROLE: Conduct field CBR rating soil utilizing the proper steps
taught.
-Setup of DCP
-Manual CBR test(s)
-Automated CBR tests
-SMP tests
-Speedy Moisture test
SAFETY BRIEF: Ensure class has received safety brief prior to conduct.
SUPERVISION & GUIDANCE: Be sure to follow the step by step directions
covered in your student outline along with the instructor’s supervision.
DEBRIEF: N/A
LP-25
soils to achieve a desired gradation or mixing commercially available
additives that may alter the gradation, change the strength and durability,
or act as a binder to cement the soil.
a. Uses. Pavement design is based on the premise that specified levels
of quality will be achieved for each soil layer in the pavement system. Each
layer must:
(1) Resist shearing within the layer.
(2) Avoid excessive elastic deflections that would result in
fatigue cracking within the layer or in overlying layers.
(3) Prevent excessive permanent deformation through
densification.
As the quality of a soil layer is increased, the ability of that layer to
distribute the load over a greater area is generally increased enough to
permit a reduction in the required thickness of the soil and surface layers.
(ON CAG #59)
b. Methods of Stabilization. The two general stabilization methods are
mechanical and additive (chemical admixture). The effectiveness of
stabilization depends on the ability to obtain uniformity in blending the
various materials. Mixing in a stationary or traveling plant is preferred.
However, other means of mixing (such as scarifiers, plows, disks, graders,
and rotary mixers) have been satisfactory.
The soil-stabilization method is determined by the amount of stabilizing
required and the conditions encountered on the project. An accurate soil
description and classification are essential for selecting the correct
materials and procedure. FM 5-410, Chapter 9, lists the most suitable
treatments for various soil types to stabilize these soils for different
objectives.
(ON CAG #60)
(1) Mechanical. Mechanical stabilization produces by compaction
an interlocking of soil-aggregate particles. The grading of the soil-
aggregate mixture must be such that a dense mass is produced when it is
compacted. Mechanical stabilization can be accomplished by uniformly mixing
the material and then compacting the mixture. As an alternative, additional
fines or aggregates maybe blended before compaction to form a uniform,
wellgraded, dense soil-aggregate mixture after compaction. The choice of
methods should be based on the gradation of the material. In some instances,
geotextiles can be used to improve a soil’s engineering characteristics.
(ON CAG #61)
(2) Additive (Chemical Admixture). Additive refers to a
manufactured commercial product that, when added to the soil in the proper
quantities, will improve the quality of the soil layer. The two types of
additive stabilization discussed mainly in are chemical and bituminous.
Chemical stabilization is achieved by the addition of proper percentages of
portland cement, lime, lime-cement-fly ash (LCF), or combinations of these
materials to the soil. Bituminous stabilization is achieved by the addition
LP-26
of proper percentages of bituminous material to the soil. Selecting and
determining the percentage of additives depend on the soil classification and
the degree of improvement in the soil quality desired. Smaller amounts of
additives are usually required to alter soil properties (such as gradation,
workability, and plasticity) than to improve the strength and durability
sufficiently to permit a thickness-reduction design. After the additive has
been mixed with the soil, spreading and compacting are achieved by
conventional means.
(a) Types.
(ON CAG #62)
1 Cement. Portland cement can be used either to
modify and improve the quality of the soil or to transform the soil into a
cemented mass with increased strength and durability. Cement can be used
effectively as a stabilizer for a wide range of materials; however, the soil
should have a PI (Plasticity Index) less than 30. For coarse-grained soils,
the amount passing the No. 4 sieve should be greater than 45 percent. The
amount of cement used depends on whether the soil is to be modified or
stabilized.
(ON CAG #63)
2 Lime. Experience shows that lime will react with
many medium-, moderately fine-, and fine-grained soils to produce decreased
plasticity, increased workability, reduced swell, and increased strength.
Soils classified according to the USCS as CH, CL, MH, ML, OH, OL, SC, SM, GC,
GM, SW-SC, SP-SC, SM-SC, GWGC, GP-GC, ML-CL, and GM-GC should be considered
as potentially capable of being stabilized with lime. Lime should be
considered with all soils having a PI greater than 10 and more than 25
percent of the soil passing the No. 200 sieve.
(ON CAG #64)
3 Fly Ash. Fly ash, when mixed with lime, can be used
effectively to stabilize most coarse- and medium-grained soils; however, the
PI should not be greater than 25. Soils classified by the USCS as SW, SP, SP-
SC, SW-SC, SW-SM, GW, GP, GP-GC, GW-GC, GP-GM, GW-GM, GC-GM, and SC-SM can be
stabilized with fly ash.
(ON CAG #65)
4 Bituminous. Most bituminous soil stabilization has
been performed with asphalt cement, cutback asphalt, and asphalt emulsions.
Soils that can be stabilized effectively with bituminous materials usually
contain less than 30 percent passing the No. 200 sieve and have a PI less
than 10. Soils classified by the USCS as SW, SP, SW-SM, SP-SM, SW-SC, SP-SC,
SM, SC, SM-SC, GW, GP, SW-GM, SP-GM, SW-GC, GP-GC, GM, GC, and GM-GC can be
effectively stabilized with bituminous materials, provided the above-
mentioned gradation and plasticity requirements are met.
(ON CAG #66)
5 Combination. Combination stabilization is
specifically defined as lime-cement, lime-asphalt, and LCF stabilization.
Combinations of lime and cement are often acceptable expedient stabilizers.
LP-27
Lime can be added to the soil to increase the soil’s workability and mixing
characteristics as well as to reduce its plasticity. Cement can then be mixed
into the soil to provide rapid strength gain. Combinations of lime and
asphalt are often acceptable stabilizers. The lime addition may prevent
stripping at the asphalt-aggregate interface and increase the mixture’s
stability.
(CAG # 67)
SUMMARY (5 MIN)
During this period of instruction we have covered: how soil is formed, the
composition of a soil mass, how to conduct a hasty field I.D. on a previously
unknown soil, CBR test, and stabilization methods. Those students with the
instructor rating forms fill them out, and turn them in. Take a Ten minute
break.
(BREAK - 10 min)
REFERENCES:
Engineering Operations MCWP 3-17
Engineering Field Data MCRP 3-17A
Military Soils Engineering MCRP 3-17.7G
Materials Testing MCRP 3-17.7H
Earthmoving Operations MCRP 3-17.7I
Recommended